KR101178263B1 - Mobile station, base station device, communication control method, and mobile communication system - Google Patents

Abstract

The mobile station 100 according to the present invention includes packet discarding units 102 and 103 configured to discard packets in uplink transmission buffers after assigning sequence numbers when predetermined conditions are satisfied.

Description

Mobile station, base station equipment, communication control method and mobile communication system {MOBILE STATION, BASE STATION DEVICE, COMMUNICATION CONTROL METHOD, AND MOBILE COMMUNICATION SYSTEM}

The present invention relates to a mobile station, a base station apparatus, a communication control method, and a mobile communication system. In particular, the present invention relates to a mobile station, a base station apparatus, a communication control method, and a mobile communication system of a long term evolution (LTE) system.

The communication method that is the successor of W-CDMA and HSDPA, that is, LTE, is examined by the 3GPP standardization organization of W-CDMA.

In LTE, it is considered that, as a radio access method, Orthogonal Frequency Division Multiplexing (OFDM) is used for downlink, and Single-Carrier Frequency Division Multiple Access (SC-FDMA) is used for uplink.

OFDM divides a specific frequency band into a plurality of narrow frequency bands (subcarriers) and loads data on each frequency object to perform transmission. According to OFDM, the subcarriers are arranged so as not to interfere with each other but partially overlap each other on the frequency, thereby realizing high-speed transmission and increasing frequency utilization efficiency.

In addition, SC-FDMA is a transmission method that can reduce interference between a plurality of mobile stations by dividing a specific frequency band and transmitting the same between a plurality of mobile stations using different frequency bands. According to the SC-FDMA, since the fluctuation of the transmission power is reduced, the power consumption and wide coverage of the mobile station can be realized.

By the way, a mobile communication system is a system which performs communication using a finite radio resource (frequency or power), and an upper limit exists in the communication capacity.

Therefore, it is necessary to limit the number of mobile stations in the cell in accordance with the communication capacity described above. For example, when a new mobile station attempts to initiate communication in the cell, when the number of mobile stations which are already communicating in the cell is large and is close to the upper limit of the communication capacity, the new mobile station, It is necessary to perform control such as disallowing to start communication in the cell.

Such control is generally referred to as call admission control or 'Call Admission Control (CAC)'.

For example, as one method of call admission control, when the number of mobile stations that are already communicating in a cell is measured, and the number of the mobile stations exceeds a predetermined threshold, the new mobile station corresponds to the corresponding mobile station. If the number of the mobile stations is lower than a predetermined threshold without allowing the cell to start communication, a method such as allowing the new mobile station to start communication in the cell may be considered.

In the above-described example, the case using the number of mobile stations already communicating in the cell has been described. However, from the viewpoint of call admission control, the new mobile station is determined in the cell based on the indicator indicating the congestion degree in the cell. It is desirable to determine whether or not communication can be initiated.

In general, a plurality of carriers exist in a mobile communication system. For example, it is assumed that a mobile communication system owns a frequency bandwidth of 20 MHz, and LTE, which has a system bandwidth of 5 MHz, is operated at the frequency bandwidth of 20 MHz. In other words, it is assumed that four LTE carriers exist.

In this case, it is preferable that the congestion degree in each of the four LTE carriers is equal from the viewpoint of effective utilization of frequency resources.

By the way, one of the services provided by the mobile communication system is a real-time service such as 'Voice Over IP (VoIP)' or 'Streaming'.

In such a real-time service, due to the nature of the service, data must be transmitted from a communication source to a communication destination within a predetermined allowable delay.

In general, in order to satisfy such a delay requirement, data of a real-time service is transmitted preferentially over data of a best effort service.

However, when the number of users performing communication of real-time services in a cell increases, the radio resources in the cell are finite, so that some users have difficulty satisfying the above-described requirements regarding delay.

From the viewpoint of call admission control, the phenomenon that there is a user who cannot satisfy such a requirement regarding such a delay becomes an index indicating the degree of congestion.

More specifically, call admission control is performed based on the number of users whose delay time of the data of the real-time service exceeds a predetermined allowable delay or the number of users whose data of the real-time service exceeds the allowable delay and is discarded. I can think of doing.

However, the conventional mobile communication system described above has the following problems.

In the LTE communication system, call admission control is performed in the base station apparatus.

In this case, since the downlink transmission buffer exists in the base station apparatus, the base station apparatus easily discards the packet due to the residence time in the transmission buffer of the real-time service packet (data) exceeding an allowable delay. It becomes possible to monitor.

On the other hand, since the uplink transmission buffer exists in the mobile station, the base station apparatus cannot directly monitor the discard of the packet due to the residence time in the transmission buffer of the real-time service data exceeding an allowable delay. .

In addition, the mobile station is configured to transmit a signal for notifying a transmission buffer status in the mobile station called a "Buffer Status Report" to the base station apparatus, but the signal stays in the transmission buffer of the mobile station to the last. This is to notify the amount of packets being made, not to notify that the packet has been discarded as the residence time exceeds the allowable delay.

Alternatively, since the mobile station assigns a sequence number to a packet of the PDCP layer and transmits it, the base station apparatus permits a dwell time in the transmission buffer of the mobile station based on the discontinuity of the sequence number of the packet of the PDCP layer. It is also conceivable to estimate that the packet has been discarded in excess of.

However, the operation of discarding after assigning a sequence number to a packet of a PDCP layer or discarding before assigning a sequence number to a packet of a PDCP layer in the mobile station is in accordance with the implementation of the mobile station and is not prescribed. not.

More specifically, Non-Patent Document 2 (TS36.323, V8.0), which prescribes the processing of the PDCP layer, does not define the operation of such a mobile station.

Therefore, it is difficult to estimate whether or not it was discarded in the transmission buffer of the mobile station due to the discontinuity of the sequence number.

Therefore, the present invention has been made in view of the above-described problems. When a packet is discarded in a transmission buffer in the mobile station, the present invention always assigns a sequence number and discards the packet. An object of the present invention is to provide a mobile station, a base station apparatus, a communication control method, and a mobile communication system that enable estimation of packet discard in a transmission buffer.

Further, the present invention performs the selection of a frequency band to be used for call admission control or communication in a cell or a frequency band to be re-granted after the completion of communication, based on the phenomenon that the above-described sequence number discontinuity has been reported from the mobile station. An object of the present invention is to provide a mobile station, a base station apparatus, a communication control method, and a mobile communication system, which make it possible to do so.

In addition, the present invention monitors the dwell time (delay amount) of data in the uplink transmission buffer, and the phenomenon that the dwell time has exceeded a predetermined threshold value, or the data in the transmission buffer of the mobile station to allow the delay. An object of the present invention is to provide a mobile station, a base station apparatus, a communication control method, and a mobile communication system that make it possible to report a phenomenon of excessive destruction to a base station apparatus.

In addition, the present invention is based on the phenomenon that the above-mentioned dwell time exceeded a predetermined threshold reported from the mobile station, or the data in the transmission buffer of the mobile station was discarded because it exceeded the allowable delay. It is an object of the present invention to provide a mobile station, a base station apparatus, a communication control method, and a mobile communication system, which enable the selection of a frequency band to be used for communication or the selection of a frequency band to be re-granted after the completion of communication.

A first feature of the present invention is a packet discard configured to discard a packet in an uplink transmission buffer when a predetermined condition is satisfied in a base station apparatus and a mobile station that transmits and receives a packet assigned a sequence number. And a packet discarding unit, and the packet discarding unit also assigns a sequence number to the discarded packet.

In the first aspect of the present invention, the packet discarding unit may be configured to discard the packet when the residence time of the packet in the transmission buffer exceeds a predetermined threshold.

In the first aspect of the present invention, the packet discarding unit may be configured to discard the packet for each logical channel or for each logical channel group.

In the first aspect of the present invention, the uplink transmission buffer may be a buffer of a PDCP layer or an RLC layer.

In the first aspect of the present invention, the packet discarding unit may be configured to assign the sequence number to the discarded packet by assigning a sequence number to all packets stored in the transmission buffer.

According to a first aspect of the present invention, the uplink transmission buffer is a buffer of a PDCP layer or an RLC layer, and the packet discarding unit is further configured to the discarded packet when the mode of the RLC layer is an Unacknowledge mode. It is comprised so that a sequence number may be provided and the said packet discarding part may be comprised so that the said discarded packet may not be provided with the said sequence number, when the mode of an RLC layer is Acknowledge mode.

According to a second aspect of the present invention, in a base station apparatus that transmits and receives a packet with a sequence number, the mobile station accepts communication by a new mobile station based on a discontinuity of sequence numbers of packets received in uplink. It is an object of the present invention to include a call acceptance control unit configured to control the control.

According to a third aspect of the present invention, there is provided a base station apparatus for transmitting and receiving a packet to which a sequence number is assigned, the discontinuous detection unit configured to detect a discontinuity of a sequence packet of a signal received in uplink; A communication unit configured to calculate the number of mobile stations or logical channels where discontinuities in the sequence numbers of the packets have occurred, and the communication by the new mobile station based on the number of mobile stations or logical channels in which the discontinuities in the sequence numbers have occurred; It is an object of the present invention to include a call acceptance control unit configured to control acceptance of a message.

A fourth aspect of the present invention is a base station apparatus for transmitting and receiving a packet to which a sequence number is assigned, the discontinuous detection unit configured to detect a discontinuity of a sequence number of a packet received in uplink; A communication unit configured to calculate the number of mobile stations or logical channels in which the discontinuity of the sequence number of the packet has occurred, and the new communication based on the number of mobile stations or the number of logical channels in which the discontinuity of the sequence number has occurred; It is essential to have a frequency band selector configured to select a frequency band to be used by a mobile station.

A fifth aspect of the present invention is a base station apparatus for transmitting and receiving a packet to which a sequence number is assigned, the discontinuous detection unit configured to detect a discontinuity of a sequence number of a received packet in uplink; A mobile station configured to calculate the number of mobile stations or the number of logical channels in which the discontinuity of the sequence number of the packet has occurred, and the mobile station which terminated the communication based on the number of mobile stations or the number of logical channels in which the discontinuity of the sequence number has occurred. It is a main point to have a frequency band selector configured to select the frequency band to be rewound.

A sixth aspect of the present invention is a communication control method in a base station apparatus and a mobile station that transmits and receives a packet assigned a sequence number, and when a predetermined condition is satisfied, discards a packet in an uplink transmission buffer. The present invention has a step of providing a sequence number to the discarded packet.

According to a seventh aspect of the present invention, there is provided a communication control method in a base station apparatus for transmitting and receiving a packet to which a sequence number is assigned, the method comprising: detecting a discontinuity of sequence numbers of received packets in uplink; Calculating a number of mobile stations or a number of logical channels where discontinuities in the sequence numbers of the packets have occurred, and controlling acceptance of communication by a new mobile station based on the number of mobile stations or the number of logical channels. Let's make a point.

An eighth aspect of the present invention is a base station apparatus for performing communication using a shared channel between a plurality of mobile stations and the plurality of mobile stations, a data server storing data transmitted from the base station apparatus, and the data. In a mobile communication system including a monitoring terminal for outputting the data stored in the server, each of the plurality of mobile stations assigns a sequence number to a packet in an uplink transmission buffer when a predetermined condition is satisfied. And a packet discarding unit configured to discard the data, and the base station apparatus includes a discontinuous detection unit configured to detect a discontinuity of a sequence number of a packet received in the uplink from the plurality of mobile stations, and a sequence number of the packet. A calculating unit configured to calculate the number of mobile stations or logical channels in which discontinuities of And a reporting unit configured to report the number of the mobile stations or the number of logical channels to the data server, wherein the data server is configured to store the number of the mobile stations or the number of logical channels as statistical values. It is essential to have a storage section and an output section configured to output the number of mobile stations or the number of logical channels to the monitoring terminal.

A ninth aspect of the present invention is a mobile station that communicates with a base station apparatus, wherein a data destroyer configured to discard data in an uplink transmission buffer when predetermined conditions are satisfied, and the base station apparatus. And a reporting section configured to report the destruction of the data.

In the ninth aspect of the present invention, the data discarding unit may be configured to discard the data when the residence time of the data in the transmission buffer exceeds a predetermined threshold.

In the ninth aspect of the present invention, the report unit may be configured to report the destruction of the data by using a measurement report for reporting a communication quality measurement result in downlink.

In the ninth aspect of the present invention, the report unit may be configured to report the destruction of the data when the number of destructions of the data or the destruction rate of the data exceeds a predetermined threshold.

In the ninth aspect of the present invention, the report unit may be configured to report that the data has been discarded in accordance with an instruction from the base station apparatus.

In the ninth aspect of the present invention, the data discarding unit is configured to discard the data for each logical channel or for each logical channel group, and the report unit discards the data for each logical channel or every logical channel group. It may be configured to report.

In the ninth aspect of the present invention, the uplink transmission buffer may be a buffer of a PDCP layer or an RLC layer.

A tenth aspect of the present invention is a base station apparatus for communicating with a mobile station, comprising: an instruction unit for instructing the mobile station to report destruction of data in an uplink transmission buffer; It is an object of the present invention to include a receiver configured to receive a report of the destruction of data in the transmission buffer.

An eleventh aspect of the present invention is a base station apparatus for communicating with a plurality of mobile stations, comprising: an instruction unit for instructing the plurality of mobile stations to report destruction of data in an uplink transmission buffer, and the plurality of mobile stations. A receiving unit configured to receive a report of the destruction of the data in the uplink transmission buffer, a calculating unit configured to calculate the number of mobile stations or logical channels where the destruction of data occurred; It is essential to have a call admission control section configured to control acceptance of communication by a new mobile station based on the number or the number of logical channels.

A twelfth aspect of the present invention is a base station apparatus for communicating with a plurality of mobile stations, comprising: an instruction unit for instructing the plurality of mobile stations to report destruction of data in an uplink transmission buffer, and the plurality of mobile stations. A receiving unit configured to receive a report of the destruction of the data in the uplink transmission buffer, a calculating unit configured to calculate the number of mobile stations or logical channels where the destruction of data occurred; It is essential to have a frequency band selector configured to select a frequency band to be used by a mobile station that is newly performing communication based on the number or the number of logical channels.

A thirteenth aspect of the present invention is a base station apparatus for communicating with a plurality of mobile stations, comprising: an instruction unit for instructing the plurality of mobile stations to report destruction of data in an uplink transmission buffer, and the plurality of mobile stations; A receiving unit configured to receive a report of the destruction of the data in the uplink transmission buffer, a calculating unit configured to calculate the number of mobile stations or logical channels where the destruction of data occurred; It is a main idea to have a frequency band selector configured to select a frequency band to which a mobile station which has finished communication should re-authorize based on the number or the number of logical channels.

According to a fourteenth aspect of the present invention, there is provided a communication control method for a mobile station that communicates with a base station apparatus, the method comprising: discarding data in an uplink transmission buffer when predetermined conditions are satisfied; In this regard, it is intended to have a step of reporting the destruction of the data.

A fifteenth aspect of the present invention is a communication control method in a base station apparatus which communicates with a plurality of mobile stations, the step of instructing the plurality of mobile stations to report the destruction of data in an uplink transmission buffer. And receiving a report of destroying data in the uplink transmission buffer from the plurality of mobile stations, calculating a number of mobile stations or logical channels for which data destruction has occurred, and the number of mobile stations. Alternatively, it is a summary to have a process of controlling acceptance of communication by a new mobile station based on the number of logical channels.

A sixteenth aspect of the present invention is a base station apparatus for performing communication using a shared channel between a plurality of mobile stations and the plurality of mobile stations, a data server storing data transmitted from the base station apparatus, and the data. A mobile communication system comprising a monitoring terminal for outputting the data stored in a server, wherein each of the plurality of mobile stations is configured to discard data in an uplink transmission buffer when predetermined conditions are satisfied. A data destruction unit and a reporting unit configured to report the destruction of the data to the base station apparatus, wherein the base station apparatus is configured to discard the data in the uplink transmission buffer from the plurality of mobile stations. The number or logic of the receiver configured to receive the report and the mobile station where the destruction of data occurred. A calculator configured to calculate the number of nulls, and a report configured to report the number of the mobile stations or the number of logical channels to the data server, wherein the data server includes the number or logic of the mobile stations. It is essential to have a storage section configured to store the number of channels as a statistical value, and an output section configured to output the number of mobile stations or the number of logical channels to the monitoring terminal.

According to a seventeenth aspect of the present invention, in a mobile station that communicates with a base station apparatus, a calculation unit configured to calculate an average time from generation of data to transmission in an uplink transmission buffer, and the average When the time exceeds a predetermined threshold, the base station apparatus has a reporting unit configured to report that the average time exceeds the predetermined threshold or the average time.

1 is an overall configuration diagram of a mobile communication system according to a first embodiment of the present invention.
2 is a functional block diagram of a mobile station according to the first embodiment of the present invention.
3 is a functional block diagram of a base station apparatus according to the first embodiment of the present invention.
4 is a flowchart showing the operation of the mobile station according to the first embodiment of the present invention.
5 is a flowchart showing the operation of the base station apparatus according to the first embodiment of the present invention.
6 is a functional block diagram of a mobile station according to the second embodiment of the present invention.
7 is a flowchart showing the operation of the mobile station according to the second embodiment of the present invention.
8 is a flowchart showing the operation of the mobile station according to the second embodiment of the present invention.

(Configuration of the mobile communication system according to the first embodiment of the present invention)

1 to 3, the configuration of a mobile communication system according to the first embodiment of the present invention will be described.

The mobile communication system 1000 according to the present embodiment is, for example, a mobile communication system to which LTE is applied, and includes a plurality of mobile stations 100 ₁ to 100 _n , a plurality of mobile stations 100 ₁ to 100 _n , and A base station apparatus 200 for performing communication using a shared channel between the base station apparatus 200, an access gateway apparatus (parent station) 300 connected to the base station apparatus 200 and the core network 400, and the base station apparatus 200 Data server 410 for storing the data transmitted from the (), and the monitoring terminal 420 to output the data stored in the data server 410.

In the example of FIG. 1, the mobile stations 100 ₁ to 100 ₃ are mobile stations performing communication in the cell 50, and the mobile station 100 _n is a mobile station which is about to start communication in the cell 50.

Here, the plurality of mobile stations 100 ₁ to 100 _n are configured to perform communication by LTE in the cell 50 with the base station apparatus 200.

That is, since a connection is established between the mobile stations 100 ₁ to 100 ₃ and the base station apparatus 200, the mobile stations 100 ₁ to 100 ₃ are in an active state.

Hereinafter, the mobile stations 100 ₁ , 100 ₂ , 100 ₃ ,..., And 100 _n have the same configuration, function, and state, and therefore, the mobile station 100 will be described as long as there is no special clue.

In the example of FIG. 1, although there is only one mobile station in the cell 50 that is about to start communication with the base station apparatus 200, two or more such mobile stations may exist.

The mobile communication system 1000 is configured to use OFDM (frequency division multiple access) for downlink and SC-FDMA (single carrier-frequency division multiple access) for uplink as a radio access method. .

Here, the communication channel in LTE is demonstrated.

For the downlink, a downlink shared physical channel (PDSCH) shared by each mobile station 100 and a downlink control channel for LTE are used.

In the downlink, information of a user or transport format mapped to a downlink shared physical channel, information of a user or transport format mapped to an uplink shared physical channel and an uplink shared physical through downlink control channels for LTE Delivery confirmation information or the like of the channel is notified, and user data is transmitted through the downlink shared physical channel.

In addition, the delivery confirmation information of the uplink shared physical channel may be transmitted through a physical HARQ indicator channel (PHICH: Physical Hybrid Indicator Channel), not the downlink control channel for LTE.

In addition, the downlink control channel for LTE mentioned above may be called a physical downlink control channel (PDCCH). More specifically, the above-described user information and transport format information mapped to the downlink shared physical channel may be referred to as downlink scheduling information.

The information of the user and the transport format mapped to the uplink shared physical channel described above may be called an Uplink Scheduling Grant.

In addition, the downlink scheduling information and the uplink scheduling grant may be collectively referred to as downlink control information (DCI).

In this case, DCI format 0 may correspond to Uplink Scheduling Grant, and DCI format 1 / 1A / 2 or the like may correspond to Downlink Scheduling Information.

As for the uplink, an uplink shared physical channel (PUSCH) shared by each mobile station 100 and an uplink control channel for LTE are used.

The uplink control channel is an uplink shared physical channel (PUCCH) at both ends of the system band, and the following control signal is transmitted by the uplink shared physical channel.

That is, in the uplink, downlink quality information (CQI) for use in scheduling, adaptive modulation and coding (AMCS) of shared physical channels in downlink by the uplink control channel for LTE. : Channel Quality Indicator and HARQ ACK information of the downlink shared physical channel are transmitted.

When the uplink shared physical channel and the control signal are transmitted at the same timing, that is, at the same subframe, the control signal is multiplexed and transmitted to the uplink shared physical channel.

In addition, user data is transmitted through the uplink shared physical channel.

As shown in FIG. 2, the mobile station 100 includes an RLC / PDCP processing unit 102, a MAC processing unit 103, an L1 processing unit 104, an amplifier unit / transceiver unit 105, and a transmission / reception antenna ( 106, a buffer monitoring unit / sequence number assigning unit 107, and a call processing unit 108 are provided.

The RLC / PDCP processing unit 102 is configured to perform Radio Link Control (RLC) layer processing and Packet Data Convergence Protocol (PDCP) layer processing.

For example, the RLC / PDCP processing unit 102, as RLC layer processing, transmits processing using uplink splitting / combining RLC retransmission control or receiving processing using downlink splitting / combining RLC retransmission control. And the like.

In addition, the RLC / PDCP processing unit 102 assigns a sequence number (SN) to a packet transmitted in uplink as PDCP processing, and performs encryption processing using the sequence number.

The packet in which the processing of the RLC or PDCP layer has been performed is data (upward data) transmitted in the uplink in the following MAC processing unit 103, and the transmission processing is performed.

The MAC processing unit 103 is configured to perform MAC (Media Access Control) layer processing.

For example, the MAC processing unit 103 is configured to perform transmission processing using MAC retransmission control (for example, HARQ: Hybrid Automatic Repeat reQuest) on uplink data as MAC layer processing.

In addition, the MAC processing unit 103 is configured to perform reception processing using MAC retransmission control for downlink data as MAC layer processing.

The L1 processing unit 104 is configured to perform layer 1 processing such as channel coding, DFT processing or IFFT processing of data transmitted through uplink, and channel decoding or FFT processing of data received through downlink. .

The amplifier unit / transmitter / receiver 105 is configured to convert the baseband signal output from the L1 processor 104 into a radio frequency band signal, and then amplify the radio frequency band signal and transmit it through the transmission / reception antenna 106. .

In addition, the amplifier unit / transceiver unit 105 amplifies the radio frequency band signal received by the transceiver antenna 106, converts the radio frequency band signal into a baseband signal, and inputs it to the L1 processing unit 104. Consists of.

The buffer monitoring unit / sequence number assigning unit 107 stores an uplink transmission buffer (the MAC layer buffer in the MAC processing unit 103 or the RLC layer buffer or the PDCP layer buffer in the RLC / PDCP processing unit 102). It is configured to monitor.

Here, the buffer monitoring unit / sequence number assigning unit 107 is configured to discard the packet in the uplink transmission buffer when a predetermined condition is satisfied.

For example, the buffer monitoring unit / sequence number assigning unit 107 is configured to discard the packet when the residence time in the uplink transmission buffer of the packet exceeds a predetermined threshold value. The residence time in the above-described transmission buffer is more specifically the elapsed time after the packet is generated and stored in the transmission buffer.

Here, the buffer monitoring unit / sequence number assigning unit 107 assigns a sequence number to the discarded packet described above, and discards the packet. In addition, the said sequence number is a sequence number of a PDCP layer, for example.

In addition, the buffer monitoring unit / sequence number assigning unit 107 may assign a sequence number to the packet immediately before discarding the packet, or hold the packet in the transmission buffer while assigning the sequence number. In the case where the above-described predetermined condition is satisfied, the packet may be discarded.

In the former case, the buffer monitoring unit / sequence number assigning unit 107 may assign a sequence number to the packet at substantially the same time as, for example, the process of discarding the packet.

On the other hand, in the latter case, the buffer monitoring unit / sequence number assigning unit 107 may assign a sequence number to the packet at the time when the packet is stored in the transmission buffer, for example.

That is, the buffer monitoring unit / sequence number assigning unit 107 may assign a sequence number to all packets stored in the transmission buffer.

In the above-described example, the case where the buffer monitoring unit / sequence number assigning unit 107 discards the packet when the residence time in the uplink transmission buffer of the packet exceeds a predetermined threshold value is used. Although shown, the buffer monitoring / sequence number assigning unit 107 can carry out the same processing in the case of discarding the packet in the uplink transmission buffer in other cases.

In addition, the case of discarding a packet in an uplink transmission buffer in other cases, for example, is a case of discarding a packet due to a buffer overflow or a packet by 'Active Queue Management (AQM)'. It is a case to destroy.

Here, AQM refers to a control method for reducing the window size of the TCP layer by discarding the packet in the transmission buffer in order to prevent the packet in the transmission buffer from rapidly increasing.

That is, when the packet in the transmission buffer is discarded, the window size of the TCP layer is reduced, and as a result, the amount of packets flowing into the transmission buffer is reduced, thereby preventing the problem of the rapid increase in the packet in the transmission buffer. It becomes possible.

The buffer monitoring unit / sequence number assigning unit 107 may be configured to discard packets in the uplink transmission buffer for each logical channel (or for each logical channel group). Also in this case, the buffer monitoring unit / sequence number assigning unit 107 assigns the sequence number to the discarded packet and then discards the packet.

Here, the logical channel group may be designated by the base station apparatus 200. The logical channel or logical channel group may be set for each communication service such as VoIP service.

Alternatively, the buffer monitoring unit / sequence number assigning unit 107 determines whether the mode of the RLC layer is 'Unacknowledged mode (UM)', 'Acknowledged mode (AM)', or 'Transparent mode (TM)'. On the basis of this, it may be configured to perform the above-mentioned processing, that is, the process of discarding the packet after assigning a sequence number to the packet.

More specifically, the buffer monitoring unit / sequence number assigning unit 107 performs the above-described process when the mode of the RLC layer is 'UM' or 'TM', and the mode of the RLC layer is 'AM'. In this case, the above-described processing may not be performed.

Alternatively, when the mode of the RLC layer is 'UM', the buffer monitoring unit / sequence number assigning unit 107 performs the above-described processing, and when the mode of the RLC layer is 'AM' or 'TM', You may be comprised so that a process mentioned above may not be performed.

In this way, after assigning the sequence number of the PDCP layer to the discarded packet in the transmission buffer of the mobile station, and discarding the packet, the base station apparatus 200 that is the receiving side of the packet receives the PDCP layer of the received packet. Based on the discontinuity of the sequence numbers, it becomes possible to easily estimate whether or not the packet is discarded in the transmission buffer of the mobile station.

The call processing unit 108 is configured to perform call processing and the like for establishing and releasing a communication channel.

Here, the RLC / PDCP processing unit 102, the buffer monitoring unit / sequence number assigning unit 107, and the call processing unit 108 may be configured to be mounted on the same IC chip, and the RLC / PDCP processing unit 102 and MAC The processing unit 103, the L1 processing unit 104, the buffer monitoring unit / sequence number assigning unit 107, and the call processing unit 108 may be configured to be mounted on the same IC chip.

As shown in FIG. 3, the base station apparatus 200 includes a transmission / reception antenna 201, an amplifier unit / transceiver unit 202, an L1 processing unit 203, a MAC processing unit 204, and an RLC / PDCP processing unit. 205, a transmission line interface 206, a calculator 207, and a call processor 208 are provided.

The amplifier / transmitter / receiver 202 is configured to convert a baseband signal output from the L1 processor 203 into a radio frequency band signal, and then amplify the radio frequency band signal and transmit it through the transmission / reception antenna 201. .

The amplifier / transmitter / receiver 202 amplifies the radio frequency band signal received by the transmission / reception antenna 201, and then converts the radio frequency band signal into a baseband signal and inputs it to the L1 processing unit 203. Consists of.

The L1 processing unit 203 is configured to perform channel encoding or IFFT processing of data transmitted through downlink, and layer 1 processing such as FFT processing, IDFT processing, and channel decoding of data received through uplink. .

The MAC processing unit 204 is configured to perform MAC layer processing. For example, the MAC processing unit 204 may perform transmission processing using MAC retransmission control (for example, HARQ: Hybrid Automatic Repeat reQuest) for downlink data, scheduling, selection of a transmission format, or the like as MAC layer processing. It is configured to perform.

The MAC processing unit 204 is configured to perform reception processing using MAC retransmission control for uplink data, scheduling, transmission format selection, and the like as MAC layer processing.

The RLC / PDCP processing unit 205 is configured to perform RLC layer processing and PDCP layer processing.

For example, the RLC / PDCP processing unit 205, as RLC layer processing, transmits processing using split-coupling-RLC retransmission control for downlink or receiving processing using split-combining-RLC retransmission control for uplink. And the like.

In addition, the RLC / PDCP processing unit 205 performs decryption on the packet received in the uplink as PDCP layer processing. At this time, the RLC / PDCP processing unit 205 can acquire the sequence number of the packet with the release of the cipher, so that it is possible to detect the discontinuity of the sequence number. This sequence number is a sequence number of a PDCP layer.

The RLC / PDCP processing unit 205 notifies the calculation unit 207 of the phenomenon that the discontinuity of the sequence number has occurred when the discontinuity of the sequence number has occurred. In addition, the RLC / PDCP processing unit 205 may notify the plurality of mobile stations 100 ₁ to 100 _n or the logical channels of the phenomenon that the discontinuity of the sequence numbers has occurred, respectively.

The transmission line interface 206 is configured to perform data transmission and reception with the access gateway device 300.

The calculator 207 is configured to receive a phenomenon from the RLC / PDCP processor 205 that a discontinuity in sequence numbers of the PDCP layers has occurred. In addition, the phenomenon that the sequence number discontinuity has occurred may be notified about the plurality of mobile stations 100 ₁ to 100 _n or their logical channels, respectively.

The calculating unit 207 is configured to calculate the number of mobile stations or the number of logical channels in which the discontinuity of the sequence number has occurred.

The calculating unit 207 notifies the call processing unit 208 of the number of mobile stations or the number of logical channels in which the discontinuity of the sequence number has occurred.

More specifically, the calculation unit 207 may set the number of mobile stations in which the number of discontinuities of the sequence number is greater than or equal to a predetermined threshold value in the predetermined monitoring section as the number of mobile stations in which the discontinuity of the sequence number has occurred.

Alternatively, the calculating unit 207 determines the number of mobile stations in which the amount of discarded packets equal to or greater than a predetermined threshold is estimated from the discontinuity of the sequence number in the predetermined monitoring section, as the number of mobile stations in which the discontinuity of the sequence number has occurred. You may also

Alternatively, the calculating unit 207 may determine that the number of mobile stations whose ratio of the amount of discarded packets to the amount of all received packets is estimated from the discontinuity of the sequence number in a predetermined monitoring section is equal to or greater than a predetermined threshold. May be the number of mobile stations in which discontinuities in sequence numbers have occurred.

The calculating unit 207 may calculate the number of mobile stations in which the discontinuity of the sequence number has occurred for each logical channel. In this case, the calculation of the number of mobile stations mentioned above is performed for the logical channel. In other words, the calculation unit 207 calculates the number of logical channels in which the discontinuity of the sequence number has occurred.

In addition, the number of mobile stations or the number of logical channels in which the discontinuity of the sequence number of the PDCP layer has occurred may be regarded as the number of mobile stations or the number of logical channels in which packet discard occurs in the transmission buffer in the mobile station. In this case, the calculating unit 207 may be configured to calculate the number of mobile stations or the number of logical channels in which packet destruction occurred in the transmission buffer in the mobile station.

In the above-described example, the discontinuity of the sequence number of the PDCP layer is detected in the RLC / PDCP processing unit 205 and the number of mobile stations in which the discontinuity of the sequence number of the PDCP layer is generated in the calculation unit 207 or By calculating the number of logical channels, the number of mobile stations or the number of logical channels for which packets were discarded in the transmission buffer in the mobile station was calculated. Instead, the RLC / PDCP processing unit 205 used the Real-time Transport Protocol (RTP). The discontinuity of the sequence number of the mobile station is detected, and the calculation unit 207 calculates the number of mobile stations or logical channels in which the discontinuity of the sequence number of the RTP has occurred, so that the discarding of packets in the transmission buffer of the mobile station has occurred. The number or the number of logical channels may be calculated.

Alternatively, if it is possible to infer the discard of the packet in the transmission buffer in the mobile station by the discontinuity of the sequence number, the packet discard occurs in the transmission buffer in the mobile station based on the discontinuity of the sequence number of the protocol other than PDCP or RTP. The number of mobile stations or the number of logical channels may be calculated.

The call processing unit 208 is configured to perform call processing such as setting up and releasing communication channels, managing the state of the base station apparatus 200, managing radio resources, and the like.

Specifically, the call processing unit 208 is configured to control the acceptance of the communication by the new mobile station based on the number of mobile stations or the number of logical channels where discarding of packets calculated by the calculation unit 207 has occurred. good.

For example, in a specific cell, when the number of mobile stations or the number of logical channels in which the sequence number of the PDCP layer has discontinued exceeds a predetermined threshold, the call processing unit 208 accepts the communication by the new mobile station. It may be configured to refuse.

In the above-described example, the call processing unit 208 is configured to reject acceptance of the communication by the new mobile station based on the number of mobile stations or the number of logical channels where the discontinuity of the sequence number of the PDCP layer has occurred. May be configured to refuse acceptance of the communication by the new mobile station based on the ratio of the mobile station or the ratio of the logical channel where the discontinuity of the sequence number of the PDCP layer has occurred.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of RRC_Connected mobile stations (the number of mobile stations of LTE_ACTIVE).

The ratio of the logical channels described above may be a ratio with respect to the total number of the logical channels set in the cell 50.

For example, in the case where the number of mobile stations having a logical channel for transmitting VoIP is set to 100, the above-described predetermined threshold value is 10%, and the number of logical channels in which discontinuity of the sequence number of the PDCP layer has occurred exceeds 10. If there is, the call processing unit 208 may be configured to refuse acceptance of the communication by the new mobile station.

In addition, the call processing section 208 is based on the number of mobile stations or the number of logical channels in which the discontinuity of the sequence number of the PDCP layer calculated by the calculation section 207 is generated. It may be configured to select.

In addition, in the above-described example, the call processing unit 208 is configured to select a frequency band to be used by the mobile station to communicate newly based on the number of mobile stations or the number of logical channels where the discontinuity of the sequence number of the PDCP layer has occurred. Although, instead, it may be configured to select a frequency band to be used by the mobile station to be newly communicated based on the ratio of the mobile station or the ratio of the logical channel where the discontinuity of the sequence number of the PDCP layer has occurred.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of RRC_Connected mobile stations (the number of mobile stations of LTE_ACTIVE). The ratio of the logical channels described above may be a ratio to the total number of the logical channels set in the cell 50.

For example, the call processing unit 208 may be configured to select a frequency band having the smallest number of mobile stations or logical channels for which a discontinuity in the sequence number of the PDCP layer has occurred, as a frequency band to be used by the mobile station that is newly communicating. good.

Further, the call processing unit 208 selects a frequency band to which the mobile station which has terminated communication should re-authorize based on the number of mobile stations or the number of logical channels in which the discontinuity of the sequence number of the PDCP layer calculated by the calculating unit 207 has occurred. It may be configured to select.

In addition, in the above-described example, the call processing unit 208 is configured to select a frequency band to which the mobile station which has terminated communication should re-authorize based on the number of mobile stations or the number of logical channels where discontinuity of the sequence number of the PDCP layer has occurred. However, instead, the mobile station which has terminated the communication may select a frequency band to be rewound based on the ratio of the mobile station or the ratio of the logical channel where the discontinuity of the sequence number of the PDCP layer has occurred.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of mobile stations of RRC_Connected (the number of mobile stations of LTE_ACTIVE). The ratio of the logical channels described above may be a ratio to the total number of the logical channels set in the cell 50.

For example, the call processing unit 208 may be configured to select a frequency band having the smallest number of mobile stations or logical channels in which the sequence number of the PDCP layer has discontinuity as a frequency band to which the mobile station which has terminated communication should re-authorize. .

In addition, the call processing unit 208 determines, via the transmission line interface 206, the number of mobile stations or the number of logical channels where the discontinuity of the sequence number of the PDCP layer calculated by the calculating unit 207 is generated, through the data server 410. ) May be configured to report.

The data server 410 according to the present embodiment is configured to store the number of mobile stations or the number of logical channels described above transmitted from the base station apparatus 200 as statistical values.

The data server 410 is configured to output the number of mobile stations or the number of logical channels described above to the monitoring terminal 420.

As a result, the operator can monitor the congestion degree in the cell by monitoring the number of mobile stations or the number of logical channels described above that are output to the monitoring terminal 420.

For example, when the operator monitors the congestion in the cell and determines that the congestion in the cell is always high or that the congestion in the cell is the maximum in one day, the cell capacity is exceeded. It is possible to determine to perform the enhancement of the facility, such as increasing the number of carriers, increasing the number of cells, or increasing the bandwidth of the carriers of the cell.

(Operation of Mobile Communication System According to First Embodiment of the Present Invention)

Referring to Fig. 4, the operation of the mobile station 100 according to the first embodiment of the present invention will be described.

As shown in Fig. 4, in step S101, the mobile station 100 measures the residence time of the packet in the uplink transmission buffer for each logical channel (or for each logical channel group). The packet may be, for example, a packet of a PDCP layer or may be a packet of an RLC layer.

In step S102, the mobile station 100 determines for each logical channel (or for each logical channel group) whether the dwell time of the packet is larger than a predetermined threshold (allowed delay).

If it is determined that the dwell time of the packet is greater than the predetermined threshold, the operation proceeds to step S103. If it is determined that the dwell time of the packet is not greater than the predetermined threshold, the operation ends.

In step S103, the mobile station 100 discards the packet after assigning a sequence number of the PDCP layer to the packet.

Further, the mobile station 100 may assign a sequence number to the packet immediately before discarding, or hold the packet in the transmission buffer while assigning the sequence number, and based on the determination in step S102, You may discard the packet. In the former case, the assignment of the sequence number is performed in the process of step S103, for example. On the other hand, in the latter case, the assignment of the sequence number may be performed, for example, before the process of step S103.

More specifically, the mobile station 100 may be configured to assign a sequence number to the discarded packet by assigning a sequence number to all packets stored in the transmission buffer.

Next, with reference to FIG. 5, operation | movement of the base station apparatus 200 which concerns on this embodiment is demonstrated.

As shown in FIG. 5, the base station apparatus 200 receives a packet in uplink in step S201.

In step S202, the base station apparatus 200 determines whether the sequence number of the packet is discontinuous.

If it is determined that the sequence number of the packet is discontinuous, the operation proceeds to step S203. If it is determined that the sequence number of the packet is not discontinuous, the operation ends.

In step S203, the base station apparatus 200 estimates that the packet has been discarded in the transmission buffer in the mobile station.

(Operation and Effects of the Mobile Communication System According to the First Embodiment of the Present Invention)

According to the mobile communication system according to the present embodiment, in the mobile station 100, when a packet in the transmission buffer of the mobile station is discarded beyond the allowable delay, the base station apparatus 200 is assigned by discarding the packet by giving a sequence number. By monitoring the discontinuity of the sequence number, it is possible to easily detect that the packet was discarded in excess of the allowable delay in the transmission buffer of the mobile station.

Further, according to the mobile communication system according to the present embodiment, the call acceptance in the cell is based on the phenomenon that a discontinuity in the uplink sequence number has occurred, that is, the packet in the transmission buffer of the mobile station has been discarded beyond the allowable delay. The selection of the frequency band to be used for control or communication or the selection of the frequency band to be re-granted after the completion of the communication can be performed.

(Mobile communication system according to second embodiment of the present invention)

6 to 8, a mobile communication system according to a second embodiment of the present invention will be described. Hereinafter, the mobile communication system according to the present embodiment will be described focusing on the differences from the mobile communication system according to the first embodiment described above.

As illustrated in FIG. 6, the mobile station 100 includes an RLC / PDCP processing unit 102, a MAC processing unit 103, an L1 processing unit 104, an amplifier unit / transceiver unit 105, and a transmission / reception antenna ( 106, a buffer monitoring unit 107A, and a call processing unit 108A.

The buffer monitoring unit 107A is configured to monitor the uplink transmission buffer (the MAC layer buffer in the MAC processing unit 103 or the RLC layer buffer or the PDCP layer buffer in the RLC / PDCP processing unit 102). .

Here, the buffer monitoring unit 107A is configured to discard data in the uplink transmission buffer when a predetermined condition is satisfied.

For example, the buffer monitoring unit 107A is configured to discard the data when the residence time of the data in the uplink transmission buffer exceeds a predetermined threshold. The residence time in the above-described transmission buffer is more specifically, the elapsed time after data is generated and stored in the transmission buffer.

The buffer monitoring unit 107A may be configured to discard data in the uplink transmission buffer for each logical channel (or for each logical channel group).

Here, the logical channel group may be designated by the base station apparatus 200. The logical channel or logical channel group may be set for each communication service such as VoIP service.

The buffer monitoring unit 107A is configured to calculate an average time from when data is generated to being transmitted in the uplink transmission buffer.

Here, the buffer monitoring unit 107A may be configured to calculate the aforementioned average time for each logical channel (or for each logical channel group).

The above-mentioned average time may calculate a value obtained by averaging the time from the generation of the data to the transmission in the uplink transmission buffer for one packet of the above-mentioned data for all the packets.

Here, one packet of the above-described data may be, for example, an RLC SDU, a PDCP data unit, an RTP packet, or a TCP packet. In addition, the above-mentioned data may generally be comprised by one or two or more packets.

In addition, "the data is generated and then transmitted" mentioned above, "until the data to be transmitted on the uplink is generated, the data is transmitted, and the delivery confirmation information (ACK) regarding the data is received" is generated. It may be defined as.

The above-described delivery confirmation information (ACK) may be delivery confirmation information of the MAC layer, delivery confirmation information of the RLC layer, or delivery confirmation information of the PDCP layer.

In addition, the above-mentioned "transmission" phenomenon is defined as "data is deleted from the transmission buffer", and data is deleted by expiration of the maximum number of retransmissions of HARQ, or data is deleted at the time of handover. Alternatively, the deletion of data due to the residence time in the buffer exceeding a predetermined threshold may be included in the above-mentioned "transmitted" phenomenon.

The call processing unit 108A is configured to perform call processing, such as setting up and releasing a communication channel.

Here, the call processing unit 108A is configured to report, to the base station apparatus 200, that the data in the uplink transmission buffer has been discarded.

For example, the call processing unit 108A is configured to report the destruction of data in the uplink transmission buffer using a measurement report for reporting a measurement result of the communication quality in the downlink. You may be.

In addition, when the average time mentioned above exceeds the predetermined threshold, the call processing part 108A may report that the above-mentioned average time exceeded the predetermined threshold or the average time using the Measurement Report. Consists of.

Here, the call processing unit 108A may be configured to transmit the measurement report in accordance with the "Event Triggered" method or the "Periodic" method specified in 3GPP TS25.133.

In addition, the "Event Triggered" method is a method of transmitting a measurement report when a specific event occurs, and the "Periodic" method is a method of periodically transmitting a measurement report.

The call processing unit 108A may be configured to transmit a measurement report in accordance with a "Time to Trigger" method or a "Pending Time After Trigger" method.

In addition, the 'Time to Trigger' method is a method of transmitting a measurement report only when the specific event continues for a predetermined time after the specific event occurs.

On the other hand, the "Pending Time After Trigger" method is a method of stopping the transmission of the Measurement Report for a predetermined period once the Measurement Report is transmitted.

Here, the Measurement Report may be an RRC message or may be header information or control information of a MAC layer. The control information of the MAC layer may be called a MAC Control Element.

In addition, the measurement report may include the above-described average time, the amount of discarded data, the number of times of data destruction, or the rate of destruction.

The call processing unit 108A may be configured to report the destruction of the data when the number of times of destruction or the rate of destruction of the data in the uplink transmission buffer exceeds a predetermined threshold.

The call processing unit 108A may be configured to report that the data in the uplink transmission buffer has been discarded in accordance with an instruction from the base station apparatus 200.

The call processing unit 108A may be configured to report that the above-described average time exceeds a predetermined threshold value or the average time in accordance with an instruction from the base station apparatus 200.

In addition, the above-mentioned instruction from the base station apparatus 200 may be notified by the control signal of the RRC layer such as Measurement Control, may be notified by the information in the System Information Block in the notification information, and the control signal of the MAC layer. May be notified by.

The call processing unit 108A may be configured to report the destruction of data in the uplink transmission buffer for each logical channel (or for each logical channel group).

The call processing unit 108A may be configured to report that the above average time exceeds a predetermined threshold value for each logical channel (or for each logical channel group) or the average time.

In addition, when the measurement processing unit transmits the measurement report according to the 'Periodic' method described above, the call processing unit 108A discards the data in the uplink transmission buffer or the above-described average time exceeds a predetermined threshold. One may be configured to report periodically.

Here, the RLC / PDCP processing unit 102, the buffer monitoring unit 107A and the call processing unit 108A may be configured to be mounted on the same IC chip, and the RLC / PDCP processing unit 102 and the MAC processing unit 103 The L1 processing unit 104, the buffer monitoring unit 107A, and the call processing unit 108A may be configured to be mounted on the same IC chip.

In the base station apparatus 200 according to the present embodiment, the calculation unit 207 is configured to receive a measurement report, which is a report of discarding data in the uplink transmission buffer, from the plurality of mobile stations 100 ₁ to 100 _n . Consists of.

In addition, when the Measurement Repoert is transmitted according to the 'Periodic' method described above, the calculation unit 207 discards the data in the uplink transmission buffer, or the average time described above exceeds a predetermined threshold. It may be configured to receive one thing periodically.

Here, the calculation unit 207 receives the measurement report through the RLC / PDCP processing unit 205 when the measurement report is an RRC message, and the measurement report when the measurement report is header information or control information of the MAC layer. It is configured to receive through the MAC processing unit 204.

The calculating unit 207 is configured to calculate the number of mobile stations or the number of logical channels where the discarding of data has occurred.

Alternatively, the calculation unit 207 reports that the average time from the plurality of mobile stations 100 ₁ to 100 _n to be transmitted after generation of data in the uplink transmission buffer exceeds a predetermined threshold. It is configured to receive a Measurement Report.

Here, the calculation unit 207 receives the measurement report through the RLC / PDCP processing unit 205 when the measurement report is an RRC message, and the measurement report when the measurement report is header information or control information of a MAC layer. Is received via the MAC processing unit 204.

The calculating section 207 is configured to calculate the number of mobile stations or the number of logical channels whose average time exceeds the predetermined threshold.

In the base station apparatus 200 according to the present embodiment, the call processing unit 208 manages call processing such as setting and releasing communication channels, state management of the base station apparatus 200, management of radio resources, and the like. It is configured to perform.

Specifically, the call processing unit 208 is configured to control acceptance of communication by the new mobile station based on the number of mobile stations or the number of logical channels where the data calculated by the calculating unit 207 has been discarded. good.

For example, in a specific cell, when the number of mobile stations or logical channels where data is discarded exceeds a predetermined threshold, the call processing unit 208 is configured to reject acceptance of communication by the new mobile station. You may be.

In the above-described example, the call processing unit 208 is configured to reject acceptance of the communication by the new mobile station based on the number of mobile stations or the number of logical channels where the discarding of data has occurred, but instead, The mobile station may be configured to refuse acceptance of the communication by the new mobile station based on the ratio of the mobile station or logical channel ratio where discarding occurred.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of mobile stations of RRC_Connected (the number of mobile stations of LTE_ACTIVE).

The ratio of the logical channels described above may be a ratio with respect to the total number of the logical channels set in the cell 50.

For example, in the case where the number of mobile stations for which the logical channel for transmitting VoIP is set is 100, the above-mentioned predetermined threshold value is 10%. When the number of logical channels where discarding of data exceeds 10, The call processing unit 208 may be configured to reject acceptance of communication by the new mobile station.

Alternatively, the call processing unit 208 accepts the communication by the new mobile station based on the number of mobile stations or the number of logical channels whose average time calculated by the calculation unit 207 exceeds the predetermined threshold. It may be configured to control.

For example, in a specific cell, when the number of mobile stations or the number of logical channels whose average time exceeds the predetermined threshold exceeds the predetermined threshold, the call processing unit 208 communicates with the new mobile station. It may be configured to refuse to accept.

In addition, in the above-described example, the call processing unit 208 is configured to reject acceptance of the communication by the new mobile station based on the number of mobile stations or the number of logical channels whose average time exceeds the predetermined threshold. Instead, the mobile terminal may be configured to refuse acceptance of the communication by the new mobile station based on the ratio of the mobile station or the ratio of the logical channel in which the above-mentioned average time exceeds a predetermined threshold.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of mobile stations of RRC_Connected (the number of mobile stations of LTE_ACTIVE).

The ratio of the logical channels described above may be a ratio to the total number of the logical channels set in the cell 50.

For example, in the case where the number of mobile stations in which the logical channels for transmitting VoIP are set is 100, the above-described predetermined threshold is 10%. If the above-mentioned average time exceeds 10, the number of logical channels exceeding the predetermined threshold is 10. When exceeding, the call processing unit 208 may be configured to reject acceptance of the communication by the new mobile station.

Further, the call processing unit 208 is configured to select a frequency band to be used by the new mobile station to communicate based on the number of mobile stations or the number of logical channels where the discard of data calculated by the calculation unit 207 has occurred. You may be.

In the above-described example, the call processing unit 208 was configured to select a frequency band to be used by the newly communicating mobile station based on the number of mobile stations or logical channels where data was discarded. For example, the frequency band to be used by the mobile station to communicate with each other may be selected based on the ratio of the mobile station or the logical channel ratio where the data is discarded.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of mobile stations of RRC_Connected (the number of mobile stations of LTE_ACTIVE). The ratio of the logical channels described above may be a ratio to the total number of the logical channels set in the cell 50.

For example, the call processing unit 208 may be configured to select a frequency band having the smallest number of mobile stations or logical channels for which data is discarded as a frequency band to be used by the mobile station that is newly communicating.

Alternatively, the call processing unit 208 should be used by the mobile station to perform new communication based on the number of mobile stations or logical channels whose average time calculated by the calculating unit 207 exceeds the predetermined threshold. The frequency band may be selected.

In addition, in the above-described example, the call processing unit 208 selects a frequency band to be used by the new mobile station to communicate based on the number of mobile stations or logical channels whose average time exceeds the predetermined threshold. It may be configured to select a frequency band to be used by the mobile station to communicate with each other based on the ratio of the mobile station or the ratio of logical channels in which the above-mentioned average time exceeds a predetermined threshold.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of mobile stations of RRC_Connected (the number of mobile stations of LTE_ACTIVE). The ratio of the logical channels described above may be a ratio to the total number of the logical channels set in the cell 50.

For example, the call processing unit 208 is configured to select a frequency band in which the number of mobile stations or the number of logical channels with the above average time exceeding a predetermined threshold value is the smallest as a frequency band to be used by a newly communicating mobile station. You may be.

Further, the call processing unit 208 is configured to select a frequency band to which the mobile station which has expired communication should re-grant based on the number of mobile stations or the number of logical channels where the discard of data calculated by the calculating unit 207 has occurred. You may be.

Further, in the above-described example, the call processing unit 208 is configured to select a frequency band to which the mobile station which has terminated communication should re-authorize based on the number of mobile stations or the number of logical channels where data was discarded. For example, the mobile station that has terminated the communication may select a frequency band to which the mobile station should re-authorize, based on the ratio of the mobile station or the logical channel ratio at which data was discarded.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of mobile stations of RRC_Connected (the number of mobile stations of LTE_ACTIVE). The ratio of the logical channels described above may be a ratio to the total number of the logical channels set in the cell 50.

For example, the call processing unit 208 may be configured to select a frequency band having the smallest number of mobile stations or logical channels for which data is discarded as a frequency band to which the mobile station which has terminated communication should re-authorize.

In addition, the call processing unit 208 is based on the number of mobile stations or the number of logical channels whose average time calculated by the calculating unit 207 exceeds a predetermined threshold value. The frequency band may be selected.

In the above-described example, the mobile station that has terminated the communication was selected as a frequency band to be re-authorized based on the number of mobile stations or the number of logical channels whose average time exceeded the predetermined threshold, but instead, The mobile station which has terminated the communication may be selected as a frequency band to be rewound based on the ratio of the mobile station or the logical channel ratio where the above average time exceeds the predetermined threshold.

In this case, the ratio of the above-mentioned mobile station may be a ratio with respect to the number of mobile stations of RRC_Connected (the number of mobile stations of LTE_ACTIVE). The ratio of the logical channels described above may be a ratio to the total number of the logical channels set in the cell 50.

For example, the call processing unit 208 is configured to select a frequency band in which the number of mobile stations or the number of logical channels with the above average time exceeding a predetermined threshold is the smallest as a frequency band to which the mobile station which has terminated communication should re-authorize. You may be.

In addition, the call processing unit 208 may include the number of mobile stations or logical channels where discarding of data calculated by the calculation unit 207 has occurred, or the number or logic of mobile stations whose average time described above exceeds a predetermined threshold. The number of channels may be configured to be reported to the data server 410 via the transmission line interface 206.

The call processing unit 208 may instruct the plurality of mobile stations 100 ₁ to 100 _n to report that the data in the uplink transmission buffer has been discarded.

Alternatively, the call processing unit 208, for the plurality of mobile stations 100 ₁ to 100 _n , has an average time from the generation of data to the transmission in the uplink transmission buffer that exceeds a predetermined threshold value, Alternatively, the average time may be reported.

In addition, the above-mentioned instruction to the plurality of mobile stations 100 ₁ to 100 _n from the call processing unit 208 in the base station apparatus 200 may be notified by a control signal of an RRC layer such as Measurement Control. The information may be notified by the information in the System Information Block, or may be notified by the control signal of the MAC layer.

The data server 410 according to the present embodiment is configured to store the number of mobile stations or the number of logical channels described above transmitted from the base station apparatus 200 as statistical values.

The data server 410 is configured to output the number of mobile stations or the number of logical channels described above to the monitoring terminal 420.

As a result, the operator can monitor the congestion degree in the cell by monitoring the number of mobile stations or the number of logical channels described above that are output to the monitoring terminal 420.

For example, when the operator monitors the congestion in the cell and determines that the congestion in the cell is always high or that the congestion in the cell is the maximum in one day, the cell capacity is exceeded. It is possible to determine to perform the enhancement of the facility, such as increasing the number of carriers, increasing the number of cells, or increasing the bandwidth of the carriers of the cell.

7 and 8, the operation of the mobile station 100 according to the second embodiment of the present invention will be described.

First, with reference to FIG. 7, the 1st operation | movement of the mobile station 100 which concerns on this embodiment is demonstrated.

As shown in Fig. 7, in step S301, the mobile station 100 measures the retention time of data in the uplink transmission buffer for each logical channel (or for each logical channel group).

In step S302, the mobile station 100 determines whether the dwell time of the data is larger than a predetermined threshold (allowed delay) for each logical channel (or for each logical channel group).

If it is determined that the dwell time of the data is greater than the predetermined threshold, the operation proceeds to step S303. If it is determined that the dwell time of the data is not greater than the predetermined threshold, the operation ends.

In step S303, the mobile station 100 discards the data.

In step S304, the mobile station 100 determines whether the number of times of data destruction or the rate of destruction of data (destruction frequency) exceeds a predetermined threshold value, or whether the amount of discarded data exceeds the predetermined threshold value. Is determined.

If it is determined that the number of times of destruction of the data or the rate of destruction of data exceeds a predetermined threshold (or the amount of discarded data exceeds the predetermined threshold), the operation proceeds to step S305 and the data If it is determined that the number of times of destruction or the rate of destruction of data does not exceed a predetermined threshold (or the amount of discarded data does not exceed the predetermined threshold), the operation ends.

In step S305, the mobile station 100 uses the Measurement Report to inform the base station apparatus 200 that the number of times of discarding the data or the rate of discarding the data exceeds a predetermined threshold (or discarded data). Amount exceeds a predetermined threshold).

Here, the mobile station 100 may report the number of times of destruction of data, the rate of destruction of data, the amount of discarded data, etc. in a measurement report.

Secondly, with reference to FIG. 8, the second operation of the mobile station 100 according to the present embodiment will be described.

As shown in Fig. 8, in step S401, the mobile station 100 measures the time between the data in the uplink transmission buffer and the time it is actually inputted to the transmission buffer and then transmitted, and in step S402, For each logical channel (or for each logical channel group), the above-described time for each data is averaged (average time).

In step S403, the mobile station 100 determines whether or not the calculated average time exceeds a predetermined threshold.

If it is determined that the average time exceeds the predetermined threshold, the operation proceeds to step S404. If it is determined that the average time does not exceed the predetermined threshold, the operation ends.

In step S404, the mobile station 100 uses the Measurement Report to report to the base station apparatus 200 that the average time exceeds a predetermined threshold.

Here, the mobile station 100 may report the averaging time together in a measurement report.

In addition, when transmitting a measurement report according to the "Periodic" method mentioned above, the said average time may exceed predetermined threshold value, and you may report the said averaging time periodically.

According to the mobile communication system according to the present embodiment, the mobile station 100 monitors the residence time (delay amount) of data in the uplink transmission buffer, and the residence time exceeds a predetermined threshold value. Alternatively, the base station apparatus 200 can report to the base station apparatus 200 that the data in the transmission buffer of the mobile station has been discarded because of an allowable delay.

Further, according to the mobile communication system according to the present embodiment, the phenomenon that the above-mentioned residence time reported from the mobile station 100 has exceeded a predetermined threshold value, or that the data in the transmission buffer of the mobile station exceeded the allowable delay, has been destroyed. Based on the phenomenon, it is possible to select a frequency band to be used for call admission control or communication in a cell or to select a frequency band to be re-granted after the completion of communication.

The above-described operations of the mobile station 100 and the radio base station 200 may be performed by hardware, may be performed by a software module executed by a processor, or may be performed by a combination of both.

Here, the software module may be, for example, a protocol stack layered in a layer structure. The processor may be hardware, for example, as a chip set, and may execute a protocol stack.

The software module may be a RAM (Random Access Memory), a flash memory, a ROM (Read Only Memory), an EPROM (Erasable Programmable ROM), an EEPROM (Electronically Erasable and Programmable ROM), a register, a hard disk, May be provided in a storage medium of any format, such as a removable disk or a CD-ROM.

The storage medium is connected to the processor so that the processor can read and write information on the storage medium. The storage medium may be integrated in a processor. The storage medium and the processor may be provided in the ASIC. The ASIC may be provided in the mobile station 100 and the radio base station 200. The storage medium and the processor may be provided in the mobile station 100 and the radio base station 200 as discrete components.

As mentioned above, although this invention was demonstrated in detail using embodiment mentioned above, it is clear for those skilled in the art that this invention is not limited to embodiment described in this specification. The present invention can be implemented as modifications and variations without departing from the spirit and scope of the invention as defined by the description of the claims. Therefore, description of this specification is for illustrative description and does not have a limiting meaning with respect to this invention.

Industrial availability

As described above, according to the present invention, the mobile station, the base station apparatus, the communication control method, and the mobile communication, which make it possible to easily estimate in the base station apparatus that the packet in the transmission buffer of the mobile station has been discarded beyond the allowable delay. A system can be provided.

Further, according to the present invention, based on the phenomenon that the sequence number of the uplink signal has a discontinuity, performing selection of a frequency band to be used for call admission control or communication in a cell or selection of a frequency band to be re-granted after the completion of communication. A mobile station, a base station apparatus, a communication control method, and a mobile communication system that make it possible can be provided.

In addition, according to the present invention, a phenomenon in which the retention time (delay amount) of data in an uplink transmission buffer is monitored and the residence time exceeds a predetermined threshold value, or the data in the transmission buffer of the mobile station is allowed to be delayed. A mobile station, a base station apparatus, a communication control method, and a mobile communication system, which make it possible to report a phenomenon of being discarded in excess to the base station apparatus, can be provided.

Further, according to the present invention, the call acceptance in the cell is based on the phenomenon that the above-mentioned dwell time exceeded a predetermined threshold reported from the mobile station, or the data in the transmission buffer of the mobile station was discarded beyond the allowable delay. A mobile station, a base station apparatus, a communication control method, and a mobile communication system capable of performing selection of a frequency band to be used for control or communication or selection of a frequency band to be re-granted after the completion of communication can be provided.

Claims (28)

A base station apparatus and a mobile station for transmitting and receiving packets of a PDCP layer assigned a sequence number,
A packet discarding unit configured to discard a packet of the PDCP layer in the transmission buffer for each logical channel when the residence time of the packet of the PDCP layer in the transmission buffer of the PDCP layer exceeds a predetermined threshold value;
The packet discarding unit is configured to assign the sequence number to a packet of the discarded PDCP layer when the mode of the RLC layer is Unacknowledge mode.
And the packet discarding unit is configured not to give the sequence number to a packet of the discarded PDCP layer when the mode of the RLC layer is Acknowledge mode. A base station apparatus for transmitting and receiving a packet of a PDCP layer assigned a sequence number to a mobile station,
A discontinuity detector configured to detect discontinuities in sequence numbers of packets of the received PDCP layer in uplink;
And a calculating unit configured to calculate a ratio of the number of packets of all PDCP layers of the number of packets of the PDCP layer where the sequence number discontinuity has occurred for each logical channel. The method of claim 2,
And a call admission control unit configured to control acceptance of communication by the new mobile station based on the ratio. A communication control method in a base station apparatus for transmitting and receiving a packet of a PDCP layer assigned a sequence number to a mobile station,
Detecting discontinuities in sequence numbers of packets of the received PDCP layer in uplink;
Calculating, for each logical channel, a ratio of the number of packets of the PDCP layer to the packet amount of all PDCP layers, in which the discontinuity of the sequence number has occurred. A base station apparatus for performing communication using a shared channel between a plurality of mobile stations and the plurality of mobile stations, a data server storing data transmitted from the base station apparatus, and the data stored in the data server. In the mobile communication system having an output terminal,
Each of the plurality of mobile stations,
A packet configured to discard a packet of the PDCP layer in the transmission buffer by assigning a sequence number to each logical channel when the residence time of the packet in the PDCP layer in the transmission buffer of the PDCP layer exceeds a predetermined threshold. With a discard;
The base station apparatus,
A discontinuity detector configured to detect discontinuities of sequence numbers of packets of the PDCP layer received in the uplink from the plurality of mobile stations;
A calculation unit configured to calculate, for each logical channel, a ratio of the number of packets of the PDCP layer to the packet amount of all PDCP layers in which the sequence number discontinuity has occurred;
A reporting unit, configured to report the ratio to the data server,
The data server,
A storage unit, configured to store the ratio as a statistical value;
And an output unit configured to output the ratio to the monitoring terminal. delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete

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